Your search keyword '"Steven A. Carr"' showing total 746 results

51. Huntingtin turnover: modulation of huntingtin degradation by cAMP-dependent protein kinase A (PKA) phosphorylation of C-HEAT domain Ser2550

Author

Yejin Lee, Hyeongju Kim, Douglas Barker, Ravi Vijayvargia, Ranjit Singh Atwal, Harrison Specht, Hasmik Keshishian, Steven A Carr, Ramee Lee, Seung Kwak, Kyung-gi Hyun, Jacob Loupe, Marcy E MacDonald, Ji-Joon Song, and Ihn Sik Seong

Subjects

Genetics, General Medicine, Molecular Biology, Genetics (clinical)

Abstract

Huntington’s disease (HD) is a neurodegenerative disorder caused by an inherited unstable HTT CAG repeat that expands further, thereby eliciting a disease process that may be initiated by polyglutamine-expanded huntingtin or a short polyglutamine-product. Phosphorylation of selected candidate residues is reported to mediate polyglutamine-fragment degradation and toxicity. Here to support the discovery of phosphosites involved in the life-cycle of (full-length) huntingtin, we employed mass spectrometry-based phosphoproteomics to systematically identify sites in purified huntingtin and in the endogenous protein by proteomic and phosphoproteomic analyses of members of an HD neuronal progenitor cell panel. Our results bring total huntingtin phosphosites to 95, with more located in the N-HEAT domain relative to numbers in the Bridge and C-HEAT domains. Moreover, phosphorylation of C-HEAT Ser2550 by cAMP-dependent protein kinase (PKA), the top hit in kinase activity screens, was found to hasten huntingtin degradation, such that levels of the catalytic subunit (PRKACA) were inversely related to huntingtin levels. Taken together, these findings highlight categories of phosphosites that merit further study and provide a phosphosite kinase pair (pSer2550-PKA) with which to investigate the biological processes that regulate huntingtin degradation and thereby influence the steady state levels of huntingtin in HD cells.

Published

2022

52. Proteomics and Population Biology in the Cardiovascular Health Study (CHS): design of a study with mentored access and active data sharing

Author

Thomas R. Austin, Caitlin P. McHugh, Jennifer A. Brody, Joshua C. Bis, Colleen M. Sitlani, Traci M. Bartz, Mary L. Biggs, Nisha Bansal, Petra Buzkova, Steven A. Carr, Christopher R. deFilippi, Mitchell S. V. Elkind, Howard A. Fink, James S. Floyd, Alison E. Fohner, Robert E. Gerszten, Susan R. Heckbert, Daniel H. Katz, Jorge R. Kizer, Rozenn N. Lemaitre, W. T. Longstreth, Barbara McKnight, Hao Mei, Kenneth J. Mukamal, Anne B. Newman, Debby Ngo, Michelle C. Odden, Ramachandran S. Vasan, Ali Shojaie, Noah Simon, George Davey Smith, Neil M. Davies, David S. Siscovick, Nona Sotoodehnia, Russell P. Tracy, Kerri L. Wiggins, Jie Zheng, and Bruce M. Psaty

Subjects

Cohort Studies, Male, Proteomics, Information Dissemination, Epidemiology, Humans, Female, Prospective Studies, Biomarkers, Bristol Population Health Science Institute

Abstract

BackgroundIn the last decade, genomic studies have identified and replicated thousands of genetic associations with measures of health and disease and contributed to the understanding of the etiology of a variety of health conditions. Proteins are key biomarkers in clinical medicine and often drug-therapy targets. Like genomics, proteomics can advance our understanding of biology.Methods and ResultsIn the setting of the Cardiovascular Health Study (CHS), a cohort study of older adults, an aptamer-based method that has high sensitivity for low-abundance proteins was used to assay 4979 proteins in frozen, stored plasma from 3188 participants (61% women, mean age 74 years). CHS provides active support, including central analysis, for seven phenotype-specific working groups (WGs). Each CHS WG is led by one or two senior investigators and includes 10 to 20 early or mid-career scientists. In this setting of mentored access, the proteomic data and analytic methods are widely shared with the WGs and investigators so that they may evaluate associations between baseline levels of circulating proteins and the incidence of a variety of health outcomes in prospective cohort analyses. We describe the design of CHS, the CHS Proteomics Study, characteristics of participants, quality control measures, and structural characteristics of the data provided to CHS WGs. We additionally highlight plans for validation and replication of novel proteomic associations.ConclusionThe CHS Proteomics Study offers an opportunity for collaborative data sharing to improve our understanding of the etiology of a variety of health conditions in older adults.

Published

2022

53. Multiple mitogenomes indicate Things Fall Apart with Out of Africa or Asia hypotheses for the phylogeographic diversity of Honey Bees (Apis mellifera)

Author

Steven M Carr

Abstract

Previous morpho-molecular studies of evolutionary relationships within the economically important genus of honey bees (Apis), including the Western Honey Bee (A. mellifera L.), have suggested Out of Africa or Asia origins and subsequent spread to Europe. I test these hypotheses by a meta-analysis of complete mitochondrial DNA coding regions (11.0 Kbp) of 22 nominal subspecies represented by 74 individual sequences of A. mellifera. Parsimony, distance, and likelihood analyses identify six nested clades: Things Fall Apart with Out of Africa or Asia hypotheses. Phylogeographic analysis shows instead a basal origin of A. m. mellifera in Europe ~780 Kya, and extension to Southeast Europe and Asia Minor ~720 Kya. European bees spread southward via a Levantine / Nilotic / Arabian corridor into Africa ~540 Kya. A circum- Mediterranean clade was re-established in Iberia ~100 Kya, and thence back through the Mediterranean islands into North Africa. Paraphyletic anomalies are artefacts of mis-referral in GenBank of sequences to the wrong subspecies, which are clarified by inclusion of multiple individuals from each subspecies. Further errors arise from reliance on faulty sequences and (or) methods of inference. Nominal subspecies within the Asia Minor and Mediterranean clades are less differentiated than are individuals within other subspecies.

Published

2023

54. Engineered allostery in light-regulated LOV-Turbo enables precise spatiotemporal control of proximity labeling in living cells

Author

Song-Yi Lee, Joleen S. Cheah, Boxuan Zhao, Charles Xu, Heegwang Roh, Christina K. Kim, Kelvin F. Cho, Namrata D. Udeshi, Steven A. Carr, and Alice Y. Ting

Subjects

Cell Biology, Molecular Biology, Biochemistry, Article, Biotechnology

Abstract

The incorporation of light-responsive domains into engineered proteins has enabled control of protein localization, interactions, and function with light. We integrated optogenetic control into proximity labeling (PL), a cornerstone technique for high-resolution proteomic mapping of organelles and interactomes in living cells. Through structure-guided screening and directed evolution, we installed the light-sensitive LOV domain into the PL enzyme TurboID to rapidly and reversibly control its labeling activity with low-power blue light. “LOV-Turbo” works in multiple contexts and dramatically reduces background in biotin-rich environments such as neurons. We used LOV-Turbo for pulse-chase labeling to discover proteins that traffick between endoplasmic reticulum, nuclear, and mitochondrial compartments under cellular stress. We also showed that instead of external light, LOV-Turbo can be activated by BRET from luciferase, enabling interaction-dependent PL. Overall, LOV-Turbo increases the spatial and temporal precision of PL, expanding the scope of experimental questions that can be addressed with PL.

Published

2023

55. Proteomic profiling of extracellular matrix components from patient metastases identifies consistently elevated proteins for developing nanobodies that target primary tumors and metastases

Author

Noor Jailkhani, Karl R. Clauser, Howard H. Mak, Steffen Rickelt, Chenxi Tian, Charles A. Whittaker, Kenneth K. Tanabe, Stephen R. Purdy, Steven A. Carr, and Richard O. Hynes

Subjects

Cancer Research, Oncology

Abstract

Metastases are hard to detect and treat, and they cause most cancer-related deaths. The relative lack of therapies targeting metastases represents a major unmet clinical need. The extracellular matrix (ECM) forms a major component of the tumor microenvironment in both primary and metastatic tumors, and certain ECM proteins can be selectively and abundantly expressed in tumors. Nanobodies against ECM proteins that show selective abundance in metastases have the potential to be used as vehicles for delivery of imaging and therapeutic cargoes. Here, we describe a strategy to develop phage-display libraries of nanobodies against ECM proteins expressed in human metastases, using as immunogens entire ECM-enriched preparations from triple-negative breast cancer (TNBC) and colorectal carcinoma (CRC) metastases to different organs as immunogens. In parallel, LC-MS/MS-based proteomics were used to define a metastasis-associated ECM signature shared by metastases from TNBC and CRC, and this conserved set of ECM proteins was selectively elevated in other tumors. As proof of concept, selective and high-affinity nanobodies were isolated against an example protein from this signature, Tenascin-C (TNC), known to be abundant in many tumor types and to play a role in metastasis. TNC was abundantly expressed in patient metastases and widely expressed across diverse metastatic sites originating from several primary tumor types. Immuno-PET/CT showed that anti-TNC nanobodies bind TNBC tumors and metastases with excellent specificity. We propose that such generic nanobodies against tumors and metastases are promising cancer-agnostic tools for delivery of therapeutics to tumor and metastatic ECM.

Published

2023

56. Supplementary Table S1 from Avadomide Induces Degradation of ZMYM2 Fusion Oncoproteins in Hematologic Malignancies

Author

Benjamin L. Ebert, Steven A. Carr, Philip P. Chamberlain, Mark Rolfe, Jean-Michel Cayuela, Jean-Jacques Kiladjian, Stéphane De Botton, Véronique Saada, Christophe Marzac, Sophie Cotteret, Rob S. Sellar, Andrew A. Guirguis, Alexander Tepper, Kaushik Viswanathan, Marie McConkey, Thomas Clayton, Mary E. Matyskiela, Namrata D. Udeshi, Pierre M. Jean Beltran, Daniel E. Grinshpun, Jessica A. Gasser, and Aline Renneville

Abstract

Supplementary Table 1. Proteomic data

Published

2023

57. Supplementary Figures S1-S11 from ZBTB33 Is Mutated in Clonal Hematopoiesis and Myelodysplastic Syndromes and Impacts RNA Splicing

Author

Benjamin L. Ebert, Siddhartha Jaiswal, Robert K. Bradley, Gad Getz, Chip Stewart, Elli Papaemmanuil, Luca Malcovati, Eva Hellstrom-Lindberg, Steven A. Carr, Kasper Lage, Donna S. Neuberg, Monkol Lek, Daniel G. MacArthur, Ruth Loos, Andrew D. Johnson, Michael H. Cho, Pinkal Desai, Bruce M. Psaty, Shankara Anand, Alex Barbera, Timothy Wood, Amaro Taylor-Weiner, Andrew Dunford, Abhishek Niroula, Mendy Miller, Joshua S. Weinstock, Alexander G. Bick, Björn Nilsson, Edyta Malolepsza, Benjamin Tanenbaum, Caroline Stanclift, Monica Schenone, Waihay Wong, Akansha Tarun, Marie McConkey, Cecilia A. Castellano, Anna Gallì, Maria Creignou, Gabriele Todisco, Emma R. Hoppe, Elsa Bernard, Matthew Leventhal, and Ellen M. Beauchamp

Abstract

Supplementary Figures S1-S11

Published

2023

58. Data from BCOR and BCORL1 Mutations Drive Epigenetic Reprogramming and Oncogenic Signaling by Unlinking PRC1.1 from Target Genes

Author

R. Coleman Lindsley, Maria E. Figueroa, Vivian J. Bardwell, Henry W. Long, Steven A. Carr, Marlise R. Luskin, Richard M. Stone, Jacqueline S. Garcia, Eric S. Winer, Rahul S. Vedula, Martin P. Carroll, Lukasz P. Gondek, Eunice S. Wang, H. Moses Murdock, Monica Schenone, Christopher J. Gibson, Yingtian Xie, Klothilda Lim, Annie Apffel, Iman Fares, Emmalee R. Adelman, Micah D. Gearhart, Paloma Cejas, Clifford A. Meyer, Hannah Q. Karp, Helen C. Wang, and Eva J. Schaefer

Abstract

Polycomb repressive epigenetic complexes are recurrently dysregulated in cancer. Unlike polycomb repressive complex 2 (PRC2), the role of PRC1 in oncogenesis and therapy resistance is not well-defined. Here, we demonstrate that highly recurrent mutations of the PRC1 subunits BCOR and BCORL1 in leukemia disrupt assembly of a noncanonical PRC1.1 complex, thereby selectively unlinking the RING-PCGF enzymatic core from the chromatin-targeting auxiliary subcomplex. As a result, BCOR-mutated PRC1.1 is localized to chromatin but lacks repressive activity, leading to epigenetic reprogramming and transcriptional activation at target loci. We define a set of functional targets that drive aberrant oncogenic signaling programs in PRC1.1-mutated cells and primary patient samples. Activation of these PRC1.1 targets in BCOR-mutated cells confers acquired resistance to treatment while sensitizing to targeted kinase inhibition. Our study thus reveals a novel epigenetic mechanism that explains PRC1.1 tumor-suppressive activity and identifies a therapeutic strategy in PRC1.1-mutated cancer.Significance:We demonstrate that BCOR and BCORL1 mutations in leukemia unlink PRC1.1 repressive function from target genes, resulting in epigenetic reprogramming and activation of aberrant cell signaling programs that mediate treatment resistance. Our study provides mechanistic insights into the pathogenesis of PRC1.1-mutated leukemia that inform novel therapeutic approaches.This article is highlighted in the In This Issue feature, p. 85

Published

2023

59. Data from Proteogenomic Markers of Chemotherapy Resistance and Response in Triple-Negative Breast Cancer

Author

Matthew J. Ellis, Shankha Satpathy, Foluso O. Ademuyiwa, Steven A. Carr, Mothaffar F. Rimawi, George Miles, Gloria V. Echeverria, Bing Zhang, Michael A. Gillette, D.R. Mani, C. Kent Osborne, Bora Lim, Jeremy Hoog, Ian S. Hagemann, Shunqiang Li, Maryam Nemati Shafaee, Julie R. Nangia, Michael T. Lewis, Tara Hiltke, Ana I. Robles, Henry Rodriguez, Lacey E. Dobrolecki, Harshavardhan Doddapaneni, Donna M. Muzny, Richard A. Gibbs, Viktoriya Korchina, Bo Wen, Zhiao Shi, Chen Huang, Xuxu Gou, Yongchao Dou, Anh Minh Tran Huynh, Tanmayi D. Vashist, Beom-Jun Kim, Erik J. Bergstrom, Jonathan T. Lei, Karsten Krug, Eric J. Jaehnig, and Meenakshi Anurag

Abstract

Microscaled proteogenomics was deployed to probe the molecular basis for differential response to neoadjuvant carboplatin and docetaxel combination chemotherapy for triple-negative breast cancer (TNBC). Proteomic analyses of pretreatment patient biopsies uniquely revealed metabolic pathways, including oxidative phosphorylation, adipogenesis, and fatty acid metabolism, that were associated with resistance. Both proteomics and transcriptomics revealed that sensitivity was marked by elevation of DNA repair, E2F targets, G2–M checkpoint, interferon-gamma signaling, and immune-checkpoint components. Proteogenomic analyses of somatic copy-number aberrations identified a resistance-associated 19q13.31–33 deletion where LIG1, POLD1, and XRCC1 are located. In orthogonal datasets, LIG1 (DNA ligase I) gene deletion and/or low mRNA expression levels were associated with lack of pathologic complete response, higher chromosomal instability index (CIN), and poor prognosis in TNBC, as well as carboplatin-selective resistance in TNBC preclinical models. Hemizygous loss of LIG1 was also associated with higher CIN and poor prognosis in other cancer types, demonstrating broader clinical implications.Significance:Proteogenomic analysis of triple-negative breast tumors revealed a complex landscape of chemotherapy response associations, including a 19q13.31–33 somatic deletion encoding genes serving lagging-strand DNA synthesis (LIG1, POLD1, and XRCC1), that correlate with lack of pathologic response, carboplatin-selective resistance, and, in pan-cancer studies, poor prognosis and CIN.This article is highlighted in the In This Issue feature, p. 2483

Published

2023

60. Supplementary Data from Avadomide Induces Degradation of ZMYM2 Fusion Oncoproteins in Hematologic Malignancies

Author

Benjamin L. Ebert, Steven A. Carr, Philip P. Chamberlain, Mark Rolfe, Jean-Michel Cayuela, Jean-Jacques Kiladjian, Stéphane De Botton, Véronique Saada, Christophe Marzac, Sophie Cotteret, Rob S. Sellar, Andrew A. Guirguis, Alexander Tepper, Kaushik Viswanathan, Marie McConkey, Thomas Clayton, Mary E. Matyskiela, Namrata D. Udeshi, Pierre M. Jean Beltran, Daniel E. Grinshpun, Jessica A. Gasser, and Aline Renneville

Abstract

Supplementary Methods, Figures, and Tables

Published

2023

61. Data from Avadomide Induces Degradation of ZMYM2 Fusion Oncoproteins in Hematologic Malignancies

Author

Benjamin L. Ebert, Steven A. Carr, Philip P. Chamberlain, Mark Rolfe, Jean-Michel Cayuela, Jean-Jacques Kiladjian, Stéphane De Botton, Véronique Saada, Christophe Marzac, Sophie Cotteret, Rob S. Sellar, Andrew A. Guirguis, Alexander Tepper, Kaushik Viswanathan, Marie McConkey, Thomas Clayton, Mary E. Matyskiela, Namrata D. Udeshi, Pierre M. Jean Beltran, Daniel E. Grinshpun, Jessica A. Gasser, and Aline Renneville

Abstract

Thalidomide analogues exert their therapeutic effects by binding to the CRL4CRBN E3 ubiquitin ligase, promoting ubiquitination and subsequent proteasomal degradation of specific protein substrates. Drug-induced degradation of IKZF1 and IKZF3 in B-cell malignancies demonstrates the clinical utility of targeting disease-relevant transcription factors for degradation. Here, we found that avadomide (CC-122) induces CRBN-dependent ubiquitination and proteasomal degradation of ZMYM2 (ZNF198), a transcription factor involved in balanced chromosomal rearrangements with FGFR1 and FLT3 in aggressive forms of hematologic malignancies. The minimal drug-responsive element of ZMYM2 is a zinc-chelating MYM domain and is contained in the N-terminal portion of ZMYM2 that is universally included in the derived fusion proteins. We demonstrate that avadomide has the ability to induce proteasomal degradation of ZMYM2–FGFR1 and ZMYM2–FLT3 chimeric oncoproteins, both in vitro and in vivo. Our findings suggest that patients with hematologic malignancies harboring these ZMYM2 fusion proteins may benefit from avadomide treatment.Significance:We extend the potential clinical scope of thalidomide analogues by the identification of a novel avadomide-dependent CRL4CRBN substrate, ZMYM2. Avadomide induces ubiquitination and degradation of ZMYM2–FGFR1 and ZMYM2–FLT3, two chimeric oncoproteins involved in hematologic malignancies, providing a proof of concept for drug-induced degradation of transcription factor fusion proteins by thalidomide analogues.

Published

2023

62. Supplementary Figures and Tables from A Ubiquitination Cascade Regulating the Integrated Stress Response and Survival in Carcinomas

Author

William C. Hahn, Francisca Vazquez, James M. McFarland, David E. Root, Steven A. Carr, Meagan E. Olive, Namrata D. Udeshi, Federica Piccioni, John Michael Krill-Burger, Joshua M. Dempster, Mariya Kazachkova, Nolan R. Bick, Alfredo Gonzalez, Nancy Dumont, Brian H. Shim, Sydney M. Moyer, Naomi Li, Lisa Leung, Linh He, Benjamin Gaeta, Ashir A. Borah, Tsukasa Shibue, and Lisa D. Cervia

Abstract

Supplementary Figure S1 shows the strategy and result of co-essentiality module identificationfrom the DepMap CRISPR screen dataset and further characterization of the BIRC6 module. Supplementary Figure S2 shows the viability effect of BIRC6 depletion in BIRC6-dependent and -nondependent cancer cells lines as well asin nontransformed cells. Supplementary Figure S3 shows in vitro confirmations of the inducible BIRC6 depletion (by RNAi and CRISPR) systems as well as the effect of BIRC6 depletion on metastasis in xenograft models. Supplementary Figure S4 shows detailed results for the allele competition assay to evaluate the role of the BIR and UBC domains of BIRC6 and further evidence for the physical assembly of BIRC6 ubiquitin ligase complex. Supplementary Figure S5 shows evidence for the selective activation of the p-eIF2alpha/ATF4 arm of UPR (or ISR) upon BIRC6 depletion. Supplementary Figure S6 shows evidence supporting the importance of HRI-mediated ISR activation as a mechanism underlying the loss of viability caused by BIRC6 complex suppression. Supplementary Figure S7 shows evidence for the direct regulation of HRI ubiquitination and degradation by the BIRC6 complex Supplementary Figure S8 shows elevated expression of HRI mRNA in the tumor samples compared to the normal samples in large-scale datasets (TCGA, TARGET and GTEx). Supplementary Figure S9 shows the inefficiency of the gene expression and copy number of the functionally related genes in predicting BIRC6 dependency. Supplementary Table S1 lists the top 50 co-essentiality modules identified in the analysis explained in Supplementary Figure S1A. Supplementary Table S2 lists the key DNA and RNA sequences used in this study.

Published

2023

63. Supplementary Figure from BCOR and BCORL1 Mutations Drive Epigenetic Reprogramming and Oncogenic Signaling by Unlinking PRC1.1 from Target Genes

Author

R. Coleman Lindsley, Maria E. Figueroa, Vivian J. Bardwell, Henry W. Long, Steven A. Carr, Marlise R. Luskin, Richard M. Stone, Jacqueline S. Garcia, Eric S. Winer, Rahul S. Vedula, Martin P. Carroll, Lukasz P. Gondek, Eunice S. Wang, H. Moses Murdock, Monica Schenone, Christopher J. Gibson, Yingtian Xie, Klothilda Lim, Annie Apffel, Iman Fares, Emmalee R. Adelman, Micah D. Gearhart, Paloma Cejas, Clifford A. Meyer, Hannah Q. Karp, Helen C. Wang, and Eva J. Schaefer

Abstract

Supplementary Figure from BCOR and BCORL1 Mutations Drive Epigenetic Reprogramming and Oncogenic Signaling by Unlinking PRC1.1 from Target Genes

Published

2023

64. Data from A Ubiquitination Cascade Regulating the Integrated Stress Response and Survival in Carcinomas

Author

William C. Hahn, Francisca Vazquez, James M. McFarland, David E. Root, Steven A. Carr, Meagan E. Olive, Namrata D. Udeshi, Federica Piccioni, John Michael Krill-Burger, Joshua M. Dempster, Mariya Kazachkova, Nolan R. Bick, Alfredo Gonzalez, Nancy Dumont, Brian H. Shim, Sydney M. Moyer, Naomi Li, Lisa Leung, Linh He, Benjamin Gaeta, Ashir A. Borah, Tsukasa Shibue, and Lisa D. Cervia

Abstract

Systematic identification of signaling pathways required for the fitness of cancer cells will facilitate the development of new cancer therapies. We used gene essentiality measurements in 1,086 cancer cell lines to identify selective coessentiality modules and found that a ubiquitin ligase complex composed of UBA6, BIRC6, KCMF1, and UBR4 is required for the survival of a subset of epithelial tumors that exhibit a high degree of aneuploidy. Suppressing BIRC6 in cell lines that are dependent on this complex led to a substantial reduction in cell fitness in vitro and potent tumor regression in vivo. Mechanistically, BIRC6 suppression resulted in selective activation of the integrated stress response (ISR) by stabilization of the heme-regulated inhibitor, a direct ubiquitination target of the UBA6/BIRC6/KCMF1/UBR4 complex. These observations uncover a novel ubiquitination cascade that regulates ISR and highlight the potential of ISR activation as a new therapeutic strategy.Significance:We describe the identification of a heretofore unrecognized ubiquitin ligase complex that prevents the aberrant activation of the ISR in a subset of cancer cells. This provides a novel insight on the regulation of ISR and exposes a therapeutic opportunity to selectively eliminate these cancer cells.See related commentary Leli and Koumenis, p. 535.This article is highlighted in the In This Issue feature, p. 517

Published

2023

65. Supplementary Tables S1-S19 from ZBTB33 Is Mutated in Clonal Hematopoiesis and Myelodysplastic Syndromes and Impacts RNA Splicing

Author

Benjamin L. Ebert, Siddhartha Jaiswal, Robert K. Bradley, Gad Getz, Chip Stewart, Elli Papaemmanuil, Luca Malcovati, Eva Hellstrom-Lindberg, Steven A. Carr, Kasper Lage, Donna S. Neuberg, Monkol Lek, Daniel G. MacArthur, Ruth Loos, Andrew D. Johnson, Michael H. Cho, Pinkal Desai, Bruce M. Psaty, Shankara Anand, Alex Barbera, Timothy Wood, Amaro Taylor-Weiner, Andrew Dunford, Abhishek Niroula, Mendy Miller, Joshua S. Weinstock, Alexander G. Bick, Björn Nilsson, Edyta Malolepsza, Benjamin Tanenbaum, Caroline Stanclift, Monica Schenone, Waihay Wong, Akansha Tarun, Marie McConkey, Cecilia A. Castellano, Anna Gallì, Maria Creignou, Gabriele Todisco, Emma R. Hoppe, Elsa Bernard, Matthew Leventhal, and Ellen M. Beauchamp

Abstract

Supplementary Tables S1-S19

Published

2023

66. Data from ZBTB33 Is Mutated in Clonal Hematopoiesis and Myelodysplastic Syndromes and Impacts RNA Splicing

Author

Benjamin L. Ebert, Siddhartha Jaiswal, Robert K. Bradley, Gad Getz, Chip Stewart, Elli Papaemmanuil, Luca Malcovati, Eva Hellstrom-Lindberg, Steven A. Carr, Kasper Lage, Donna S. Neuberg, Monkol Lek, Daniel G. MacArthur, Ruth Loos, Andrew D. Johnson, Michael H. Cho, Pinkal Desai, Bruce M. Psaty, Shankara Anand, Alex Barbera, Timothy Wood, Amaro Taylor-Weiner, Andrew Dunford, Abhishek Niroula, Mendy Miller, Joshua S. Weinstock, Alexander G. Bick, Björn Nilsson, Edyta Malolepsza, Benjamin Tanenbaum, Caroline Stanclift, Monica Schenone, Waihay Wong, Akansha Tarun, Marie McConkey, Cecilia A. Castellano, Anna Gallì, Maria Creignou, Gabriele Todisco, Emma R. Hoppe, Elsa Bernard, Matthew Leventhal, and Ellen M. Beauchamp

Abstract

Clonal hematopoiesis results from somatic mutations in cancer driver genes in hematopoietic stem cells. We sought to identify novel drivers of clonal expansion using an unbiased analysis of sequencing data from 84,683 persons and identified common mutations in the 5-methylcytosine reader ZBTB33 as well as in YLPM1, SRCAP, and ZNF318. We also identified these mutations at low frequency in patients with myelodysplastic syndrome. Zbtb33-edited mouse hematopoietic stem and progenitor cells exhibited a competitive advantage in vivo and increased genome-wide intron retention. ZBTB33 mutations potentially link DNA methylation and RNA splicing, the two most commonly mutated pathways in clonal hematopoiesis and myelodysplastic syndromes.Significance:Mutations in known driver genes can be found in only about half of individuals with clonal hematopoiesis. Here, we performed a somatic mutation discovery effort in nonmalignant blood samples, which identified novel candidate genes that may play biological roles in hematopoietic stem cell expansion and hematologic malignancies.This article is highlighted in the In This Issue feature, p. 403

Published

2023

67. Supplementary Figure from Proteogenomic Markers of Chemotherapy Resistance and Response in Triple-Negative Breast Cancer

Author

Matthew J. Ellis, Shankha Satpathy, Foluso O. Ademuyiwa, Steven A. Carr, Mothaffar F. Rimawi, George Miles, Gloria V. Echeverria, Bing Zhang, Michael A. Gillette, D.R. Mani, C. Kent Osborne, Bora Lim, Jeremy Hoog, Ian S. Hagemann, Shunqiang Li, Maryam Nemati Shafaee, Julie R. Nangia, Michael T. Lewis, Tara Hiltke, Ana I. Robles, Henry Rodriguez, Lacey E. Dobrolecki, Harshavardhan Doddapaneni, Donna M. Muzny, Richard A. Gibbs, Viktoriya Korchina, Bo Wen, Zhiao Shi, Chen Huang, Xuxu Gou, Yongchao Dou, Anh Minh Tran Huynh, Tanmayi D. Vashist, Beom-Jun Kim, Erik J. Bergstrom, Jonathan T. Lei, Karsten Krug, Eric J. Jaehnig, and Meenakshi Anurag

Abstract

Supplementary Figure from Proteogenomic Markers of Chemotherapy Resistance and Response in Triple-Negative Breast Cancer

Published

2023

68. Supplementary Data from BCOR and BCORL1 Mutations Drive Epigenetic Reprogramming and Oncogenic Signaling by Unlinking PRC1.1 from Target Genes

Author

R. Coleman Lindsley, Maria E. Figueroa, Vivian J. Bardwell, Henry W. Long, Steven A. Carr, Marlise R. Luskin, Richard M. Stone, Jacqueline S. Garcia, Eric S. Winer, Rahul S. Vedula, Martin P. Carroll, Lukasz P. Gondek, Eunice S. Wang, H. Moses Murdock, Monica Schenone, Christopher J. Gibson, Yingtian Xie, Klothilda Lim, Annie Apffel, Iman Fares, Emmalee R. Adelman, Micah D. Gearhart, Paloma Cejas, Clifford A. Meyer, Hannah Q. Karp, Helen C. Wang, and Eva J. Schaefer

Abstract

Supplementary Data from BCOR and BCORL1 Mutations Drive Epigenetic Reprogramming and Oncogenic Signaling by Unlinking PRC1.1 from Target Genes

Published

2023

69. Supplementary Table from Proteogenomic Markers of Chemotherapy Resistance and Response in Triple-Negative Breast Cancer

Author

Matthew J. Ellis, Shankha Satpathy, Foluso O. Ademuyiwa, Steven A. Carr, Mothaffar F. Rimawi, George Miles, Gloria V. Echeverria, Bing Zhang, Michael A. Gillette, D.R. Mani, C. Kent Osborne, Bora Lim, Jeremy Hoog, Ian S. Hagemann, Shunqiang Li, Maryam Nemati Shafaee, Julie R. Nangia, Michael T. Lewis, Tara Hiltke, Ana I. Robles, Henry Rodriguez, Lacey E. Dobrolecki, Harshavardhan Doddapaneni, Donna M. Muzny, Richard A. Gibbs, Viktoriya Korchina, Bo Wen, Zhiao Shi, Chen Huang, Xuxu Gou, Yongchao Dou, Anh Minh Tran Huynh, Tanmayi D. Vashist, Beom-Jun Kim, Erik J. Bergstrom, Jonathan T. Lei, Karsten Krug, Eric J. Jaehnig, and Meenakshi Anurag

Abstract

Supplementary Table from Proteogenomic Markers of Chemotherapy Resistance and Response in Triple-Negative Breast Cancer

Published

2023

70. Supplementary Data from Rictor Phosphorylation on the Thr-1135 Site Does Not Require Mammalian Target of Rapamycin Complex 2

Author

Dos D. Sarbassov, David M. Sabatini, Mark A. Magnuson, Steven A. Carr, Hasmik Keshishian, Terri A. Addona, Timothy R. Peterson, Nitin K. Agarwal, Tattym Shaikenov, Chien-Hung Chen, and Delphine Boulbes

Abstract

Supplementary Data from Rictor Phosphorylation on the Thr-1135 Site Does Not Require Mammalian Target of Rapamycin Complex 2

Published

2023

71. Data from Rictor Phosphorylation on the Thr-1135 Site Does Not Require Mammalian Target of Rapamycin Complex 2

Author

Dos D. Sarbassov, David M. Sabatini, Mark A. Magnuson, Steven A. Carr, Hasmik Keshishian, Terri A. Addona, Timothy R. Peterson, Nitin K. Agarwal, Tattym Shaikenov, Chien-Hung Chen, and Delphine Boulbes

Abstract

In animal cells, growth factors coordinate cell proliferation and survival by regulating the phosphoinositide 3-kinase/Akt signaling pathway. Deregulation of this signaling pathway is common in a variety of human cancers. The PI3K-dependent signaling kinase complex defined as mammalian target of rapamycin complex 2 (mTORC2) functions as a regulatory Ser-473 kinase of Akt. We find that activation of mTORC2 by growth factor signaling is linked to the specific phosphorylation of its component rictor on Thr-1135. The phosphorylation of this site is induced by the growth factor stimulation and expression of the oncogenic forms of ras or PI3K. Rictor phosphorylation is sensitive to the inhibition of PI3K, mTOR, or expression of integrin-linked kinase. The substitution of wild-type rictor with its specific phospho-mutants in rictor null mouse embryonic fibroblasts did not alter the growth factor–dependent phosphorylation of Akt, indicating that the rictor Thr-1135 phosphorylation is not critical in the regulation of the mTORC2 kinase activity. We found that this rictor phosphorylation takes place in the mTORC2-deficient cells, suggesting that this modification might play a role in the regulation of not only mTORC2 but also the mTORC2-independent function of rictor. Mol Cancer Res; 8(6); 896–906. ©2010 AACR.

Published

2023

72. Data from Castration Resistance in Prostate Cancer Is Mediated by the Kinase NEK6

Author

William C. Hahn, Peter S. Hammerman, Philip W. Kantoff, Jacob D. Jaffe, Monica Schenone, Steven A. Carr, Emily Hartman, Jinal Patel, Yvonne Y. Li, Michaela Bowden, Isil Guney, Francesca Izzo, Ying Jie Lock, Katherine Labella, Rosina T. Lis, Maura B. Cotter, Anna C. Schinzel, and Atish D. Choudhury

Abstract

In prostate cancer, the development of castration resistance is pivotal in progression to aggressive disease. However, understanding of the pathways involved remains incomplete. In this study, we performed a high-throughput genetic screen to identify kinases that enable tumor formation by androgen-dependent prostate epithelial (LHSR-AR) cells under androgen-deprived conditions. In addition to the identification of known mediators of castration resistance, which served to validate the screen, we identified a mitotic-related serine/threonine kinase, NEK6, as a mediator of androgen-independent tumor growth. NEK6 was overexpressed in a subset of human prostate cancers. Silencing NEK6 in castration-resistant cancer cells was sufficient to restore sensitivity to castration in a mouse xenograft model system. Tumors in which castration resistance was conferred by NEK6 were predominantly squamous in histology with no evidence of AR signaling. Gene expression profiling suggested that NEK6 overexpression stimulated cytoskeletal, differentiation, and immune signaling pathways and maintained gene expression patterns normally decreased by castration. Phosphoproteome profiling revealed the transcription factor FOXJ2 as a novel NEK6 substrate, with FOXJ2 phosphorylation associated with increased expression of newly identified NEK6 transcriptional targets. Overall, our studies establish NEK6 signaling as a central mechanism mediating castration-resistant prostate cancer. Cancer Res; 77(3); 753–65. ©2016 AACR.

Published

2023

73. Supplementary File 1 from Mass Spectrometry–Based Proteomics Reveals Potential Roles of NEK9 and MAP2K4 in Resistance to PI3K Inhibition in Triple-Negative Breast Cancers

Author

Cynthia X. Ma, Steven A. Carr, Jason M. Held, R. Reid Townsend, Matthew J. Ellis, David Fenyö, Li Ding, Christopher J. Yoon, Kuan-lin Huang, Gary L. Johnson, Sherri R. Davies, Jingqin Luo, Feng Gao, Karl R. Clauser, D.R. Mani, Emily Kawaler, Xuya Wang, Xiaowei Wang, Dean P. Edwards, Shixia Huang, Tina Primeau, Petra Erdmann-Gilmore, Jeremy Hoog, Zhanfang Guo, Karsten Krug, Michael A. Gillette, Philipp Mertins, Arshag D. Mooradian, Kelly V. Ruggles, Shunqiang Li, Sandeep Rajput, and Filip Mundt

Abstract

mRNA isoforms

Published

2023

74. Supplementary Methods from Castration Resistance in Prostate Cancer Is Mediated by the Kinase NEK6

Author

William C. Hahn, Peter S. Hammerman, Philip W. Kantoff, Jacob D. Jaffe, Monica Schenone, Steven A. Carr, Emily Hartman, Jinal Patel, Yvonne Y. Li, Michaela Bowden, Isil Guney, Francesca Izzo, Ying Jie Lock, Katherine Labella, Rosina T. Lis, Maura B. Cotter, Anna C. Schinzel, and Atish D. Choudhury

Abstract

Description of additional methods and procedures used in the study.

Published

2023

75. Supplementary Figures from Proteomic Profiling of the ECM of Xenograft Breast Cancer Metastases in Different Organs Reveals Distinct Metastatic Niches

Author

Richard O. Hynes, Steven A. Carr, John M. Lamar, Genevieve Abbruzzese, Alexandra Naba, Samuel A. Myers, and Jess D. Hebert

Abstract

Supplementary Figures S1 to S10. Supplementary Figure S1. Quality control western blots; Supplementary Figure S2. Label-free matrisome protein abundance; Supplementary Figure S3. Label-free percentage protein abundance; Supplementary Figure S4. Proteins identified in only one TMT 10-plex; Supplementary Figure S5. Tumor-cell-only proteins; Supplementary Figure S6. Abundance of tumor-cell-derived and stroma-derived matrisome proteins in metastases to different tissues; Supplementary Figure S7. Stromal proteins elevated in metastases relative to normal tissue; Supplementary Figure S8. Alterations in SERPINB1 are associated with lower progression-free survival; Supplementary Figure S9. Additional proteins evaluated for altered metastatic tropism; Supplementary figure S10. Gene Set Enrichment Analysis of ECM proteins and predicted upstream regulators in brain metastases.

Published

2023

76. Supplementary Table S3 from Castration Resistance in Prostate Cancer Is Mediated by the Kinase NEK6

Author

William C. Hahn, Peter S. Hammerman, Philip W. Kantoff, Jacob D. Jaffe, Monica Schenone, Steven A. Carr, Emily Hartman, Jinal Patel, Yvonne Y. Li, Michaela Bowden, Isil Guney, Francesca Izzo, Ying Jie Lock, Katherine Labella, Rosina T. Lis, Maura B. Cotter, Anna C. Schinzel, and Atish D. Choudhury

Abstract

GO terms for NEK6 upregulated genes Day 5 after castration (filtered for >10 GeneHits).

Published

2023

77. Figure S1 from BRG1 Loss Predisposes Lung Cancers to Replicative Stress and ATR Dependency

Author

Carla F. Kim, Tyler Jacks, Steven A. Carr, Lee Zou, Kwok-Kin Wong, Aaron N. Hata, Alice T. Shaw, Roderick T. Bronson, Angeliki Karatza, Hai Hu, Fei Li, Audris Oh, Chendi Li, D.R. Mani, Monica Schenone, Caroline R. Stanclift, Mary C. Beytagh, Margherita Paschini, Antoine Simoneau, Jonathan Y. Kim, Patrizia Pessina, Francisco J. Sanchez-Rivera, Christine F. Brainson, Arjun Bhutkar, Hasmik Keshishian, Caroline G. Fahey, Carla P. Concepcion, and Manav Gupta

Abstract

Figure S1 shows detailed RNA-sequencing analysis of patient samples as well as murine isogenic cell lines. Also presented here is further characterization of human isogenic models of BRG1 loss.

Published

2023

78. Supplementary Tables from Proteomic Profiling of the ECM of Xenograft Breast Cancer Metastases in Different Organs Reveals Distinct Metastatic Niches

Author

Richard O. Hynes, Steven A. Carr, John M. Lamar, Genevieve Abbruzzese, Alexandra Naba, Samuel A. Myers, and Jess D. Hebert

Abstract

Supplementary Tables S1 through S5. Supplementary Table S1. Overview of nomenclature; Supplementary Table S2. Overview of tandem mass tag (TMT) assignment; Supplementary Table S3. shRNA sequences; Supplementary Table S4. sgRNA sequences; Supplementary Table S5. qPCR primers used.

Published

2023

79. Ingenuity Pathway Analysis from Proteomic Profiling of the ECM of Xenograft Breast Cancer Metastases in Different Organs Reveals Distinct Metastatic Niches

Author

Richard O. Hynes, Steven A. Carr, John M. Lamar, Genevieve Abbruzzese, Alexandra Naba, Samuel A. Myers, and Jess D. Hebert

Abstract

IPA predictions of potential upstream regulators

Published

2023

80. Supplementary File 2 from Mass Spectrometry–Based Proteomics Reveals Potential Roles of NEK9 and MAP2K4 in Resistance to PI3K Inhibition in Triple-Negative Breast Cancers

Author

Cynthia X. Ma, Steven A. Carr, Jason M. Held, R. Reid Townsend, Matthew J. Ellis, David Fenyö, Li Ding, Christopher J. Yoon, Kuan-lin Huang, Gary L. Johnson, Sherri R. Davies, Jingqin Luo, Feng Gao, Karl R. Clauser, D.R. Mani, Emily Kawaler, Xuya Wang, Xiaowei Wang, Dean P. Edwards, Shixia Huang, Tina Primeau, Petra Erdmann-Gilmore, Jeremy Hoog, Zhanfang Guo, Karsten Krug, Michael A. Gillette, Philipp Mertins, Arshag D. Mooradian, Kelly V. Ruggles, Shunqiang Li, Sandeep Rajput, and Filip Mundt

Abstract

Pharmacodynamic changes (pathways)

Published

2023

81. MS data from Proteomic Profiling of the ECM of Xenograft Breast Cancer Metastases in Different Organs Reveals Distinct Metastatic Niches

Author

Richard O. Hynes, Steven A. Carr, John M. Lamar, Genevieve Abbruzzese, Alexandra Naba, Samuel A. Myers, and Jess D. Hebert

Abstract

Original mass spectrometry data used for analysis

Published

2023

82. Figure legends for supplementary figures from BRG1 Loss Predisposes Lung Cancers to Replicative Stress and ATR Dependency

Author

Carla F. Kim, Tyler Jacks, Steven A. Carr, Lee Zou, Kwok-Kin Wong, Aaron N. Hata, Alice T. Shaw, Roderick T. Bronson, Angeliki Karatza, Hai Hu, Fei Li, Audris Oh, Chendi Li, D.R. Mani, Monica Schenone, Caroline R. Stanclift, Mary C. Beytagh, Margherita Paschini, Antoine Simoneau, Jonathan Y. Kim, Patrizia Pessina, Francisco J. Sanchez-Rivera, Christine F. Brainson, Arjun Bhutkar, Hasmik Keshishian, Caroline G. Fahey, Carla P. Concepcion, and Manav Gupta

Abstract

All figure legends for supplementary figures included here.

Published

2023

83. Supplementary Table 1 from BRG1 Loss Predisposes Lung Cancers to Replicative Stress and ATR Dependency

Author

Carla F. Kim, Tyler Jacks, Steven A. Carr, Lee Zou, Kwok-Kin Wong, Aaron N. Hata, Alice T. Shaw, Roderick T. Bronson, Angeliki Karatza, Hai Hu, Fei Li, Audris Oh, Chendi Li, D.R. Mani, Monica Schenone, Caroline R. Stanclift, Mary C. Beytagh, Margherita Paschini, Antoine Simoneau, Jonathan Y. Kim, Patrizia Pessina, Francisco J. Sanchez-Rivera, Christine F. Brainson, Arjun Bhutkar, Hasmik Keshishian, Caroline G. Fahey, Carla P. Concepcion, and Manav Gupta

Abstract

Differential RNA-seq analysis and list of all gene ontology and cancer reactome pathways found for top differentially upregulated genes in BRG1 mutant lung cancer patients compared to BRG1 wildtype patients, in the TCGA, PanCancer databases.

Published

2023

84. Data from Phosphorylation of RAB7 by TBK1/IKKϵ Regulates Innate Immune Signaling in Triple-Negative Breast Cancer

Author

Thanh U. Barbie, David A. Barbie, Steven A. Carr, Jacob D. Jaffe, Saemi Han, Brandon P. Piel, Erik H. Knelson, Philipp Mertins, Navin R. Mahadevan, Tran C. Thai, Zehua Zhu, and Jessica L. Ritter

Abstract

Triple-negative breast cancer (TNBC) is a heterogeneous disease enriched for mutations in PTEN and dysregulation of innate immune signaling. Here, we demonstrate that Rab7, a recently identified substrate of PTEN phosphatase activity, is also a substrate of the innate immune signaling kinases TANK-binding kinase 1 (TBK1)/IκB kinase ϵ (IKKϵ) on the same serine-72 (S72) site. An unbiased search for novel TBK1/IKKϵ substrates using stable isotope labeling with amino acids in cell culture phosphoproteomic analysis identified Rab7-S72 as a top hit. PTEN-null TNBC cells expressing a phosphomimetic version of Rab7-S72 exhibited diffuse cytosolic Rab7 localization and enhanced innate immune signaling, in contrast to a kinase-resistant version, which localized to active puncta that promote lysosomal-mediated stimulator of interferon genes (STING) degradation. Thus, convergence of PTEN loss and TBK1/IKKϵ activation on Rab7-S72 phosphorylation limited STING turnover and increased downstream production of IRF3 targets including CXCL10, CCL5, and IFNβ. Consistent with this data, PTEN-null TNBC tumors expressed higher levels of STING, and PTEN-null TNBC cell lines were hyperresponsive to STING agonists. Together, these findings begin to uncover how innate immune signaling is dysregulated downstream of TBK1/IKKϵ in a subset of TNBCs and reveals previously unrecognized cross-talk with STING recycling that may have implications for STING agonism in the clinic.Significance:These findings identify Rab7 as a substrate for TBK1 for regulation of innate immune signaling, thereby providing important insight for strategies aimed at manipulating the immune response to enhance therapeutic efficacy in TNBC.

Published

2023

85. Supplementary Table 5 from BRG1 Loss Predisposes Lung Cancers to Replicative Stress and ATR Dependency

Author

Carla F. Kim, Tyler Jacks, Steven A. Carr, Lee Zou, Kwok-Kin Wong, Aaron N. Hata, Alice T. Shaw, Roderick T. Bronson, Angeliki Karatza, Hai Hu, Fei Li, Audris Oh, Chendi Li, D.R. Mani, Monica Schenone, Caroline R. Stanclift, Mary C. Beytagh, Margherita Paschini, Antoine Simoneau, Jonathan Y. Kim, Patrizia Pessina, Francisco J. Sanchez-Rivera, Christine F. Brainson, Arjun Bhutkar, Hasmik Keshishian, Caroline G. Fahey, Carla P. Concepcion, and Manav Gupta

Abstract

Cancer dependency analysis in pan cancer datasets - DRIVE and ACHILLES.

Published

2023

86. Supplementary File 4 from Mass Spectrometry–Based Proteomics Reveals Potential Roles of NEK9 and MAP2K4 in Resistance to PI3K Inhibition in Triple-Negative Breast Cancers

Author

Cynthia X. Ma, Steven A. Carr, Jason M. Held, R. Reid Townsend, Matthew J. Ellis, David Fenyö, Li Ding, Christopher J. Yoon, Kuan-lin Huang, Gary L. Johnson, Sherri R. Davies, Jingqin Luo, Feng Gao, Karl R. Clauser, D.R. Mani, Emily Kawaler, Xuya Wang, Xiaowei Wang, Dean P. Edwards, Shixia Huang, Tina Primeau, Petra Erdmann-Gilmore, Jeremy Hoog, Zhanfang Guo, Karsten Krug, Michael A. Gillette, Philipp Mertins, Arshag D. Mooradian, Kelly V. Ruggles, Shunqiang Li, Sandeep Rajput, and Filip Mundt

Abstract

Response markers

Published

2023

87. Extended Methods from Mass Spectrometry–Based Proteomics Reveals Potential Roles of NEK9 and MAP2K4 in Resistance to PI3K Inhibition in Triple-Negative Breast Cancers

Author

Cynthia X. Ma, Steven A. Carr, Jason M. Held, R. Reid Townsend, Matthew J. Ellis, David Fenyö, Li Ding, Christopher J. Yoon, Kuan-lin Huang, Gary L. Johnson, Sherri R. Davies, Jingqin Luo, Feng Gao, Karl R. Clauser, D.R. Mani, Emily Kawaler, Xuya Wang, Xiaowei Wang, Dean P. Edwards, Shixia Huang, Tina Primeau, Petra Erdmann-Gilmore, Jeremy Hoog, Zhanfang Guo, Karsten Krug, Michael A. Gillette, Philipp Mertins, Arshag D. Mooradian, Kelly V. Ruggles, Shunqiang Li, Sandeep Rajput, and Filip Mundt

Abstract

Extended Materials and Methods with in depth details about experimental procedures and protocols

Published

2023

88. Supplementary Table 2 from BRG1 Loss Predisposes Lung Cancers to Replicative Stress and ATR Dependency

Author

Carla F. Kim, Tyler Jacks, Steven A. Carr, Lee Zou, Kwok-Kin Wong, Aaron N. Hata, Alice T. Shaw, Roderick T. Bronson, Angeliki Karatza, Hai Hu, Fei Li, Audris Oh, Chendi Li, D.R. Mani, Monica Schenone, Caroline R. Stanclift, Mary C. Beytagh, Margherita Paschini, Antoine Simoneau, Jonathan Y. Kim, Patrizia Pessina, Francisco J. Sanchez-Rivera, Christine F. Brainson, Arjun Bhutkar, Hasmik Keshishian, Caroline G. Fahey, Carla P. Concepcion, and Manav Gupta

Abstract

Differential RNA-seq analysis and list of all gene ontology and cancer reactome pathways found for top differentially upregulated genes in isogenic murine Brg1 knockout lung cancer cells compared to Brg1 wildtype cells.

Published

2023

89. Supplementary Data from Phosphorylation of RAB7 by TBK1/IKKϵ Regulates Innate Immune Signaling in Triple-Negative Breast Cancer

Author

Thanh U. Barbie, David A. Barbie, Steven A. Carr, Jacob D. Jaffe, Saemi Han, Brandon P. Piel, Erik H. Knelson, Philipp Mertins, Navin R. Mahadevan, Tran C. Thai, Zehua Zhu, and Jessica L. Ritter

Abstract

SF1: Unaltered immunoblots for Fig 4E. SF2: Unaltered immunoblots for Fig 4F. SF3: Unaltered immunoblots for Fig 4G. SF4: Additional phosphopeptide analysis for cell based and in vitro SILAC screen. SF5: Lower magnification (40X) of basal expression of V5 and Rab7 in mutants, to correspond with Fig 4A. SF6: EGFR and STING localization following TBK1/IKKE inhibition. SF7: Schematic for Rab7S72 role in regulating STING/TBK1/IKKE signaling in TNBCs. STableS3: Primer sequence for qRT-PCR. STableS4: List of antibodies. STableS5: PTEN/STING Staining of a TNBC TMA.

Published

2023

90. Titles for supplementary tables from BRG1 Loss Predisposes Lung Cancers to Replicative Stress and ATR Dependency

Author

Carla F. Kim, Tyler Jacks, Steven A. Carr, Lee Zou, Kwok-Kin Wong, Aaron N. Hata, Alice T. Shaw, Roderick T. Bronson, Angeliki Karatza, Hai Hu, Fei Li, Audris Oh, Chendi Li, D.R. Mani, Monica Schenone, Caroline R. Stanclift, Mary C. Beytagh, Margherita Paschini, Antoine Simoneau, Jonathan Y. Kim, Patrizia Pessina, Francisco J. Sanchez-Rivera, Christine F. Brainson, Arjun Bhutkar, Hasmik Keshishian, Caroline G. Fahey, Carla P. Concepcion, and Manav Gupta

Abstract

All titles for supplementary tables included here.

Published

2023

91. Supplementary Table 4 from BRG1 Loss Predisposes Lung Cancers to Replicative Stress and ATR Dependency

Author

Carla F. Kim, Tyler Jacks, Steven A. Carr, Lee Zou, Kwok-Kin Wong, Aaron N. Hata, Alice T. Shaw, Roderick T. Bronson, Angeliki Karatza, Hai Hu, Fei Li, Audris Oh, Chendi Li, D.R. Mani, Monica Schenone, Caroline R. Stanclift, Mary C. Beytagh, Margherita Paschini, Antoine Simoneau, Jonathan Y. Kim, Patrizia Pessina, Francisco J. Sanchez-Rivera, Christine F. Brainson, Arjun Bhutkar, Hasmik Keshishian, Caroline G. Fahey, Carla P. Concepcion, and Manav Gupta

Abstract

Mass spectrometry-based enrichment of proteins quantified using Baf47 interaction in isogenic Brg1 wildtype and knockout cells. List includes details about identification and quantitation of proteins and is sorted by logFC.

Published

2023

92. Marker selection from Proteomic Profiling of the ECM of Xenograft Breast Cancer Metastases in Different Organs Reveals Distinct Metastatic Niches

Author

Richard O. Hynes, Steven A. Carr, John M. Lamar, Genevieve Abbruzzese, Alexandra Naba, Samuel A. Myers, and Jess D. Hebert

Abstract

Marker selection analysis to identify proteins elevated in each metastatic tissue

Published

2023

93. Supplementary File 3 from Mass Spectrometry–Based Proteomics Reveals Potential Roles of NEK9 and MAP2K4 in Resistance to PI3K Inhibition in Triple-Negative Breast Cancers

Author

Cynthia X. Ma, Steven A. Carr, Jason M. Held, R. Reid Townsend, Matthew J. Ellis, David Fenyö, Li Ding, Christopher J. Yoon, Kuan-lin Huang, Gary L. Johnson, Sherri R. Davies, Jingqin Luo, Feng Gao, Karl R. Clauser, D.R. Mani, Emily Kawaler, Xuya Wang, Xiaowei Wang, Dean P. Edwards, Shixia Huang, Tina Primeau, Petra Erdmann-Gilmore, Jeremy Hoog, Zhanfang Guo, Karsten Krug, Michael A. Gillette, Philipp Mertins, Arshag D. Mooradian, Kelly V. Ruggles, Shunqiang Li, Sandeep Rajput, and Filip Mundt

Abstract

Pharmacodynamic markers

Published

2023

94. GSEA gene sets from Proteomic Profiling of the ECM of Xenograft Breast Cancer Metastases in Different Organs Reveals Distinct Metastatic Niches

Author

Richard O. Hynes, Steven A. Carr, John M. Lamar, Genevieve Abbruzzese, Alexandra Naba, Samuel A. Myers, and Jess D. Hebert

Abstract

Gene sets used to perform GSEA

Published

2023

95. Supplementary Table 1 from Phosphorylation of RAB7 by TBK1/IKKϵ Regulates Innate Immune Signaling in Triple-Negative Breast Cancer

Author

Thanh U. Barbie, David A. Barbie, Steven A. Carr, Jacob D. Jaffe, Saemi Han, Brandon P. Piel, Erik H. Knelson, Philipp Mertins, Navin R. Mahadevan, Tran C. Thai, Zehua Zhu, and Jessica L. Ritter

Abstract

Phosphopeptides from cell based screen

Published

2023

96. Supplementary tables 1 and 2 from Mass Spectrometry–Based Proteomics Reveals Potential Roles of NEK9 and MAP2K4 in Resistance to PI3K Inhibition in Triple-Negative Breast Cancers

Author

Cynthia X. Ma, Steven A. Carr, Jason M. Held, R. Reid Townsend, Matthew J. Ellis, David Fenyö, Li Ding, Christopher J. Yoon, Kuan-lin Huang, Gary L. Johnson, Sherri R. Davies, Jingqin Luo, Feng Gao, Karl R. Clauser, D.R. Mani, Emily Kawaler, Xuya Wang, Xiaowei Wang, Dean P. Edwards, Shixia Huang, Tina Primeau, Petra Erdmann-Gilmore, Jeremy Hoog, Zhanfang Guo, Karsten Krug, Michael A. Gillette, Philipp Mertins, Arshag D. Mooradian, Kelly V. Ruggles, Shunqiang Li, Sandeep Rajput, and Filip Mundt

Abstract

Supplementary tables 1 and 2; Clinical information about the patients that the PDX models were established from and pathways that are regulated in the sensitive tumors after buparlisib treatment, respectively.

Published

2023

97. Supplementary File 5 from Mass Spectrometry–Based Proteomics Reveals Potential Roles of NEK9 and MAP2K4 in Resistance to PI3K Inhibition in Triple-Negative Breast Cancers

Author

Cynthia X. Ma, Steven A. Carr, Jason M. Held, R. Reid Townsend, Matthew J. Ellis, David Fenyö, Li Ding, Christopher J. Yoon, Kuan-lin Huang, Gary L. Johnson, Sherri R. Davies, Jingqin Luo, Feng Gao, Karl R. Clauser, D.R. Mani, Emily Kawaler, Xuya Wang, Xiaowei Wang, Dean P. Edwards, Shixia Huang, Tina Primeau, Petra Erdmann-Gilmore, Jeremy Hoog, Zhanfang Guo, Karsten Krug, Michael A. Gillette, Philipp Mertins, Arshag D. Mooradian, Kelly V. Ruggles, Shunqiang Li, Sandeep Rajput, and Filip Mundt

Abstract

Response markers (pathways)

Published

2023

98. Supplementary Figure Legends from Castration Resistance in Prostate Cancer Is Mediated by the Kinase NEK6

Author

William C. Hahn, Peter S. Hammerman, Philip W. Kantoff, Jacob D. Jaffe, Monica Schenone, Steven A. Carr, Emily Hartman, Jinal Patel, Yvonne Y. Li, Michaela Bowden, Isil Guney, Francesca Izzo, Ying Jie Lock, Katherine Labella, Rosina T. Lis, Maura B. Cotter, Anna C. Schinzel, and Atish D. Choudhury

Abstract

Legend for Supplemental Figures S1-S6.

Published

2023

99. Data from Proteomic Profiling of the ECM of Xenograft Breast Cancer Metastases in Different Organs Reveals Distinct Metastatic Niches

Author

Richard O. Hynes, Steven A. Carr, John M. Lamar, Genevieve Abbruzzese, Alexandra Naba, Samuel A. Myers, and Jess D. Hebert

Abstract

Metastasis causes most cancer-related deaths, and one poorly understood aspect of metastatic cancer is the adaptability of cells from a primary tumor to create new niches and survive in multiple, different secondary sites. We used quantitative mass spectrometry to analyze the extracellular matrix (ECM), a critical component of metastatic niches, in metastases to the brain, lungs, liver, and bone marrow, all derived from parental MDA-MB-231 triple-negative breast cancer cells. Tumor and stromal cells cooperated in forming niches; stromal cells produced predominantly core, structural ECM proteins and tumor cells produced a diverse array of ECM-associated proteins, including secreted factors and modulators of the matrix. In addition, tumor and stromal cells together created distinct niches in each tissue. Downregulation of SERPINB1, a protein elevated in brain metastases, led to a reduction in brain metastasis, suggesting that some niche-specific ECM proteins may be involved in metastatic tropism.Significance:Tumor and stromal cells together create distinct ECM niches in breast cancer metastases to various tissues, providing new insight into how tumor cells adapt to survive in different tissue environments.

Published

2023

100. Data from Mass Spectrometry–Based Proteomics Reveals Potential Roles of NEK9 and MAP2K4 in Resistance to PI3K Inhibition in Triple-Negative Breast Cancers

Author

Cynthia X. Ma, Steven A. Carr, Jason M. Held, R. Reid Townsend, Matthew J. Ellis, David Fenyö, Li Ding, Christopher J. Yoon, Kuan-lin Huang, Gary L. Johnson, Sherri R. Davies, Jingqin Luo, Feng Gao, Karl R. Clauser, D.R. Mani, Emily Kawaler, Xuya Wang, Xiaowei Wang, Dean P. Edwards, Shixia Huang, Tina Primeau, Petra Erdmann-Gilmore, Jeremy Hoog, Zhanfang Guo, Karsten Krug, Michael A. Gillette, Philipp Mertins, Arshag D. Mooradian, Kelly V. Ruggles, Shunqiang Li, Sandeep Rajput, and Filip Mundt

Abstract

Activation of PI3K signaling is frequently observed in triple-negative breast cancer (TNBC), yet PI3K inhibitors have shown limited clinical activity. To investigate intrinsic and adaptive mechanisms of resistance, we analyzed a panel of patient-derived xenograft models of TNBC with varying responsiveness to buparlisib, a pan-PI3K inhibitor. In a subset of patient-derived xenografts, resistance was associated with incomplete inhibition of PI3K signaling and upregulated MAPK/MEK signaling in response to buparlisib. Outlier phosphoproteome and kinome analyses identified novel candidates functionally important to buparlisib resistance, including NEK9 and MAP2K4. Knockdown of NEK9 or MAP2K4 reduced both baseline and feedback MAPK/MEK signaling and showed synthetic lethality with buparlisib in vitro. A complex in/del frameshift in PIK3CA decreased sensitivity to buparlisib via NEK9/MAP2K4–dependent mechanisms. In summary, our study supports a role for NEK9 and MAP2K4 in mediating buparlisib resistance and demonstrates the value of unbiased omic analyses in uncovering resistance mechanisms to targeted therapy.Significance: Integrative phosphoproteogenomic analysis is used to determine intrinsic resistance mechanisms of triple-negative breast tumors to PI3K inhibition. Cancer Res; 78(10); 2732–46. ©2018 AACR.

Published

2023